BEGIN:VCALENDAR VERSION:2.0 PRODID:Linklings LLC BEGIN:VTIMEZONE TZID:Asia/Tokyo X-LIC-LOCATION:Asia/Tokyo BEGIN:STANDARD TZOFFSETFROM:+0900 TZOFFSETTO:+0900 TZNAME:JST DTSTART:18871231T000000 END:STANDARD END:VTIMEZONE BEGIN:VEVENT DTSTAMP:20250110T023312Z LOCATION:Hall B5 (2)\, B Block\, Level 5 DTSTART;TZID=Asia/Tokyo:20241203T171600 DTEND;TZID=Asia/Tokyo:20241203T172800 UID:siggraphasia_SIGGRAPH Asia 2024_sess110_papers_1049@linklings.com SUMMARY:Dynamic Neural Radiosity with Multi-grid Decomposition DESCRIPTION:Technical Papers\n\nRui Su, Honghao Dong, Jierui Ren, Haojie J in, Yisong Chen, Guoping Wang, and Sheng Li (Peking University)\n\nPrior a pproaches to the neural rendering of global illumination typically rely on complex network architectures and training strategies to model the global effects. This often leads to impractically high overheads for both traini ng and inference. The neural radiosity technique marks a significant advan cement by injecting the radiometric prior into the training process, allow ing for efficient modeling of the global radiance fields using a lightweig ht network and grid-based representations. However, this method encounters difficulties in modeling dynamic scenes, as the high-dimensional feature space quickly becomes unmanageable as the number of varying scene paramete rs grows. In this work, we extend neural radiosity for variable scenes thr ough a novel neural decomposition method. To achieve this, we first parame terize the animated scene with an explicit vector $\mathbf{v}$, which cond itions a high-dimensional radiance field $L_{\theta}$. We then develop a p ractical representation for $L_{\theta}$ by decomposing the high-dimension al feature grid into 3D grids, 2D feature planes, and lightweight MLPs. Th is strategy effectively models the correlation between 3D spatial features and dynamic scene variables, while maintaining a practical memory and com putational cost. Experimental results show that our method facilitates eff icient dynamic global illumination rendering with practical runtime perfor mance, outperforming previous state-of-the-art techniques with both reduce d training and inference costs.\n\nRegistration Category: Full Access, Ful l Access Supporter\n\nLanguage Format: English Language\n\nSession Chair: Michael Wimmer (TU Wien) URL:https://asia.siggraph.org/2024/program/?id=papers_1049&sess=sess110 END:VEVENT END:VCALENDAR